White Papers

This white paper provides a high level overview of the Mentor reference flow for ARM architecture.

Customers are integrating single or multiple ARM(r) Cortex(tm)-A15 processors into their SoC designs in order to take advantage of this industry-leading IP. In order to perform manufacturing test for the SoC, a test strategy needs to be adopted and the corresponding DFT implemented to achieve that test strategy. Traditionally, it has been up to the design-for-test (DFT) engineer to understand the test strategy and implement the DFT associated with it.

With the introduction of this jointly developed Mentor reference flow for ARM architecture, DFT engineers now have a guide so they can effectively and efficiently test designs that include the ARM Cortex-A15 processor.

This white paper describes the functionality of user defined fault models (UDFM), including gate exhaustive UDFM and cell-aware UDFM, and the effectiveness of lowering DPM in devices.

To achieve today's quality and defect-per-million (DPM) goals, high-quality testing must achieve very high defect coverage. Testing today typically consists of generating test patterns based on multiple fault models that emulate manufacturing defects. Commonly used fault models include stuck-at, bridging and transition.

With each step down in process node size, there are new defects introduced into the manufacturing process. Many of these defects may be detected via the existing fault models and test pattern generation methods, but there are cases where in order to maximize coverage, a new fault model needs to be created.

This white paper describes the known common manufacturing defects and methods for detecting defects.

At design nodes smaller than 90 nm, manufacturing test challenges grow exponentially as compared to larger design nodes. At larger design nodes, manufacturing defects were typically a bridge or open that could be detected using a stuck-at tests. At smaller design nodes defects that effect at-speed performance are becoming more common and slow speed testing will not detect them.

Larger designs and the growing population of non-stuck defects have led many companies to adopt test compression techniques. In fact, the Embedded Deterministic Test (EDT) technology within TestKompress has now been used in roughly one billion production chips. There has been a surge of compression techniques promoted in the industry since TestKompress was released in 2003. So, why has TestKompress become the standard approach in industry? This paper will try to explain the technology behind the various compression techniques and their robustness in the presence of Xs, false and multi cycle paths, low pin access, and other design factors.

The manufacturing test process for ICs is increasing in cost and effort to keep up with rigorous quality standards, complexity of newer designs and process nodes, narrower time-to-market windows, and demand to reduce test pins.  DFT engineers are using advanced fault models to improve test quality. However, increasing test time and volume, which translates into increased cost, is forcing many companies to apply the necessary tests in fewer test cycles and, if possible, with fewer pins.  Low Pin Count Test (LPCT) is a technique to reduce the cost of test by minimizing the pin requirements of a device when tested on an ATE. By applying LPCT, devices can be easily tested on structural DFT testers at dramatically reduced costs while meeting the low pin count requirements of device and design flow.  Combining LPCT with test compression further extends the test capabilities to allow application of all necessary fault models using low-cost testers that are seriously pin-limited. The techniques described here enable gains in test coverage with less application time and minimal effects on design and test overhead.

There are several applications where logic built-in self-test (BIST) is an important test approach and valuable methodology. This paper describes the most common use of logic BIST as supported by Tessent™ LogicBIST and common tradeoffs on when and where to apply logic BIST.